U.S. patent application number 10/498987 was filed with the patent office on 2005-04-21 for optical fiber feed-through.
Invention is credited to Ichikawa, Susumu, Onosato, Yoichi, Watanabe, Akio.
Application Number | 20050084227 10/498987 |
Document ID | / |
Family ID | 27759677 |
Filed Date | 2005-04-21 |
United States Patent
Application |
20050084227 |
Kind Code |
A1 |
Onosato, Yoichi ; et
al. |
April 21, 2005 |
Optical fiber feed-through
Abstract
This optical-fiber feedthrough is constituted of a metallic
sleeve 1 and an optical fiber 2 fastened thereto, and the metallic
sleeve 1 is characterized by being constituted of i) a sleeve main
body having a first hollow portion 9 which has an inner diameter
larger than the outer diameter of the optical-fiber bare fiber
uncovered portion 3 in the optical fiber 2 and into which the
optical-fiber bare fiber uncovered portion is inserted, and a
second hollow portion 8 which communicates with the first hollow
portion and has an inner diameter larger than the outer diameter of
the resin-covered portion 5 in the optical fiber and in which an
inserted portion of the resin-covered portion and an optical-fiber
bare fiber uncovered portion standing uncovered from the
resin-covered portion to lead to the first hollow portion are held
and ii) a first conical recessed portion 10 which is provided on
the first hollow portion side of the sleeve main body and to which
the leading end portion of the optical-fiber bare fiber uncovered
portion is uncovered.
Inventors: |
Onosato, Yoichi; (Tokyo,
JP) ; Ichikawa, Susumu; (Tokyo, JP) ;
Watanabe, Akio; (Tokyo, JP) |
Correspondence
Address: |
ARMSTRONG, KRATZ, QUINTOS, HANSON & BROOKS, LLP
1725 K STREET, NW
SUITE 1000
WASHINGTON
DC
20006
US
|
Family ID: |
27759677 |
Appl. No.: |
10/498987 |
Filed: |
June 25, 2004 |
PCT Filed: |
February 19, 2003 |
PCT NO: |
PCT/JP03/01766 |
Current U.S.
Class: |
385/138 ;
385/80 |
Current CPC
Class: |
G02B 6/4248
20130101 |
Class at
Publication: |
385/138 ;
385/080 |
International
Class: |
G02B 006/36 |
Foreign Application Data
Date |
Code |
Application Number |
Feb 22, 2002 |
JP |
2002-45714 |
Jan 22, 2003 |
JP |
2003-13139 |
Claims
1. An optical-fiber feedthrough which has i) an optical fiber
constituted of a resin-covered portion at which the surface of an
optical-fiber bare fiber is covered and an optical-fiber bare fiber
uncovered portion standing uncovered from the resin-covered portion
and provided on the outer surface thereof with a metallic film and
ii) a metallic sleeve with which the optical fiber is fastened, and
which is to be attached to the package sidewall of an optical
communication module so that the optical fiber is guided into the
optical communication module, wherein; said metallic sleeve
comprises: a sleeve main body having a first hollow portion which
has an inner diameter larger than the outer diameter of the
optical-fiber bare fiber uncovered portion in the optical fiber and
into which the optical-fiber bare fiber uncovered portion is
inserted, and a second hollow portion which communicates with this
first hollow portion and has an inner diameter larger than the
outer diameter of the resin-covered portion in the optical fiber
and in which an inserted portion of the resin-covered portion and
an optical-fiber bare fiber uncovered portion standing uncovered
from the resin-covered portion to lead to the first hollow portion
are held; and a first conical recessed portion which is provided on
the first hollow portion side of the sleeve main body and to which
the leading end portion of the optical-fiber bare fiber uncovered
portion is uncovered; the interior of said first conical recessed
portion being filled with a solder to make the optical-fiber bare
fiber uncovered portion fastened to the metallic sleeve and also
make a gap between the first hollow portion and the optical-fiber
bare fiber uncovered portion being closed with the solder, and a
gap between the second hollow portion and the resin-covered portion
being filled with an adhesive to make the resin-covered portion
fastened to the metallic sleeve.
2. The optical-fiber feedthrough according to claim 1, wherein a
cutout is provided at the second hollow portion of said metallic
sleeve.
3. The optical-fiber feedthrough according to claim 2, wherein the
leading end portion of the inserted portion of the optical fiber at
its resin-covered portion is disposed at a position intermediate or
substantially intermediate between said cutout and the open end
portion of said second hollow portion on its side opposite to the
first hollow portion, and said second hollow portion is filled
therein with the adhesive at least up to an end of the cutout on
its first hollow portion side, and also a hollow is formed between
an end of the second hollow portion on its first hollow portion
side and an end of the adhesive on its first hollow portion side
with which the second hollow portion is filled.
4. The optical-fiber feedthrough according to claim 2 or 3, wherein
said cutout has a circular shape or substantially circular shape of
from 0.2 mm or more to 0.9 mm or less in inner diameter.
5. The optical-fiber feedthrough according to claims 1 to 3,
wherein said metallic sleeve is provided on the surface thereof
with a subbing layer formed of an Ni and/or Cr plating layer and a
surface layer formed of an Au plating layer.
6. The optical-fiber feedthrough according to claim 1, wherein a
terminal component part to be held in the package of the optical
communication module is set in said metallic sleeve on its first
conical recessed portion side, where this terminal component part
is constituted of i) a terminal component part main body having a
third hollow portion which has an inner diameter larger than the
outer diameter of the optical-fiber bare fiber uncovered portion
and into which the optical-fiber bare fiber uncovered portion
extending outward from the first conical recessed portion is
inserted and ii) a second conical recessed portion which is
provided in this terminal component part main body on its side
opposite to the metallic sleeve and to which the leading end
portion of the optical-fiber bare fiber uncovered portion is
uncovered, and also the interior of this second conical recessed
portion is filled with a solder to make the optical-fiber bare
fiber uncovered portion fastened to the terminal component part and
a gap between the third hollow portion and the optical-fiber bare
fiber uncovered portion is closed with the solder.
7. The optical-fiber feedthrough according to claim 6, wherein; an
auxiliary cylindrical portion is provided which extends outward
from the peripheral edge portion of the second conical recessed
portion in said terminal component part main body, and also has a
sixth hollow portion which communicates with said third hollow
portion and has an inner diameter larger than this third hollow
portion, to protect the leading end of the optical-fiber bare fiber
uncovered portion standing uncovered from the second conical
recessed portion; and the leading end portion of said optical-fiber
bare fiber uncovered portion has been subjected to end face
treatment for optical coupling.
8. The optical-fiber feedthrough according to claim 1, wherein the
terminal component part to be held inside the package of the
optical communication module is set in said metallic sleeve on its
first conical recessed portion side, where this terminal component
part is constituted of i) a terminal component part main body
having a fourth hollow portion which has an inner diameter larger
than the outer diameter of the optical-fiber bare fiber uncovered
portion and into which the optical-fiber bare fiber uncovered
portion is inserted and a fifth hollow portion which communicates
with this fourth hollow portion and has an inner diameter larger
than the fourth hollow portion and in which the optical-fiber bare
fiber uncovered portion extending outward from the first conical
recessed portion of the metallic sleeve is held and ii) a second
conical recessed portion which is provided in this terminal
component part main body on its side opposite to the metallic
sleeve and to which the leading end portion of the optical-fiber
bare fiber uncovered portion is uncovered, and also the interior of
this second conical recessed portion is filled with a solder to
make the optical-fiber bare fiber uncovered portion fastened to the
terminal component part and a gap between the fourth hollow portion
and the optical-fiber bare fiber uncovered portion is closed with
the solder.
9. The optical-fiber feedthrough according to claim 8, wherein; an
auxiliary cylindrical portion is provided which extends outward
from the peripheral edge portion of the second conical recessed
portion in said terminal component part main body, and also has a
sixth hollow portion which communicates with said fourth hollow
portion and has an inner diameter larger than this fourth hollow
portion, to protect the leading end of the optical-fiber bare fiber
uncovered portion standing uncovered from the second conical
recessed portion; and the leading end portion of said optical-fiber
bare fiber uncovered portion has been subjected to end face
treatment for optical coupling.
10. The optical-fiber feedthrough according to any one of claims 6
to 9, wherein said terminal component part is provided on the
surface thereof with a subbing layer formed of an Ni and/or Cr
plating layer and a surface layer formed of an Au plating
layer.
11. The optical-fiber feedthrough according to claim 7 or 9,
wherein a cutout is provided at the sixth hollow portion of said
auxiliary cylindrical portion.
Description
TECHNICAL FIELD
[0001] This invention relates to an optical-fiber feedthrough that
can make hermetic sealing for guiding an optical fiber into an
optical communication module such as a semiconductor laser module
or a semiconductor amplifier module, used in optical communication
or the like. More particularly, it relates to an improvement of an
optical-fiber feedthrough that can make an optical-fiber bare fiber
not easily break when it is attached to a package sidewall of the
optical communication module.
BACKGROUND ART
[0002] In optical communication modules such as semiconductor laser
modules and semiconductor amplifier modules, a semiconductor
element and an optical fiber are optically coupled inside the
package. If the package is not-hermetically sealed, any moisture
having entered it from the outside may condense in the package to
cause difficulties such that the optical element deteriorates and
electrodes electrically short. Accordingly, what comes important is
the structure of hermetic sealing between the package and the
optical fiber.
[0003] Hitherto, methods have been proposed in a large number and
have been put into practical use. What is commonest is a method in
which a pipelike metallic sleeve is interposed between the package
and the optical fiber to seal the package hermetically.
[0004] For example, Japanese Patent Application Laid-open No.
H8-15572 discloses an optical-fiber feedthrough having a structure
having i) an optical fiber constituted of a resin-covered portion
at which the surface of an optical-fiber bare fiber is covered and
an optical-fiber bare fiber uncovered portion standing uncovered
from this resin-covered portion and ii) a pipe (metallic sleeve)
with which this optical fiber is fastened, where the pipe and the
optical-fiber bare fiber uncovered portion are soldered at the gap
between them, and the gap between the pipe and the resin-covered
portion are filled with an adhesive to bond them. Japanese Patent
Application Laid-open No. H8-114723 also discloses an optical-fiber
feedthrough having a structure having i) an optical fiber
constituted of a first cover layer with which the surface of an
optical-fiber bare fiber is covered, a second cover layer with
which the first cover layer is covered and an optical-fiber bare
fiber uncovered portion standing uncovered from the first cover
layer and ii) an optical-fiber guide-in sleeve member (metallic
sleeve) with which this optical fiber is fastened, where this
optical-fiber guide-in sleeve member is constituted of a first
columnar hollow portion into which an optical fiber with the second
cover layer can be inserted, a second columnar hollow portion which
communicates with the first one and into which an optical fiber
with a first cover layer smaller in diameter than the first
columnar hollow portion and a third columnar hollow portion which
communicates with the second one and has a diameter larger than the
second columnar hollow portion and in which the first cover layer
and the optical-fiber bare fiber are held, where the air space
between the optical fiber with the second cover layer and the first
columnar hollow portion is filled with an adhesive to bond them,
the air space between the first cover layer, the optical-fiber bare
fiber and the third columnar hollow portion is filled with a
solder, and a cover of an adhesive is provided at the leading end
portion of the solder.
[0005] The metallic sleeve of this optical-fiber feedthrough is
fastened to the package sidewall of the optical communication
module by soldering or seam welding to effect hermetic sealing.
[0006] Now, in the optical-fiber feedthrough disclosed in Japanese
Patent Application Laid-open No. H8-15572, the portion fastened
with solder and the portion fastened with resin adjoin to each
other inside the pipe (metallic sleeve). Hence, when the metallic
sleeve of the optical-fiber feedthrough is soldered or seam-welded
to the package sidewall of the optical communication module, the
heat of the soldering or seam welding tends to be conducted to the
resin-covered portion of the optical fiber and to the resin
(adhesive) with which the optical fiber is fastened to the metallic
sleeve, so that, at the worst, it has occurred that the stress to
the optical fiber due to the deformation of the resin makes the
optical-fiber bare fiber break.
[0007] In the optical-fiber feedthrough disclosed in Japanese
Patent Application Laid-open No. H8-114723, too, the portion
fastened with solder and the portion fastened with resin are
adjacent to each other inside the optical-fiber guide-in sleeve
member (metallic sleeve). Hence, like the optical-fiber feedthrough
disclosed in Japanese Patent Application Laid-open No. H8-15572,
there has been a problem that the optical-fiber bare fiber tends to
break when the metallic sleeve of the optical-fiber feedthrough is
soldered or seam-welded to the package sidewall of the optical
communication module.
[0008] The present invention has been made taking note of such
problems. Accordingly, an object of the present invention is to
provide an optical-fiber feedthrough that can make the
optical-fiber bare fiber not easily break when it is attached to
the package sidewall of the optical communication module.
[0009] Another object of the present invention is to provide an
optical-fiber feedthrough that enables sealing treatment by a
simple method, making use of a solder having a higher melting point
than any conventional one, and enables the optical communication
module to be manufactured stably and to have highly reliable
sealing structure.
[0010] Still another object of the present invention is to provide
an optical-fiber feedthrough that can make the optical fiber not
easily come out of the optical-fiber feedthrough when the optical
fiber is pulled (i.e., has a high pull strength).
DISCLOSURE OF THE INVENTION
[0011] Accordingly, the present inventors have made extensive
studies on the optical-fiber feedthrough in order to achieve the
above objects. As a result, they have discovered an optical-fiber
feedthrough structure that enables hermetic sealing in a high
reliability as the optical communication module when it is fastened
to the package sidewall of the optical communication module by
soldering or seam welding.
[0012] That is, the present invention is an optical-fiber
feedthrough which has i) an optical fiber constituted of a
resin-covered portion at which the surface of an optical-fiber bare
fiber is covered and an optical-fiber bare fiber uncovered portion
standing uncovered from the resin-covered portion and provided on
the outer surface thereof with a metallic film and ii) a metallic
sleeve with which the optical fiber is fastened, and which is to be
attached to the package sidewall of an optical communication module
so that the optical fiber is guided into the optical communication
module, wherein;
[0013] the metallic sleeve comprises:
[0014] a sleeve main body having a first hollow portion which has
an inner diameter larger than the outer diameter of the
optical-fiber bare fiber uncovered portion in the optical fiber and
into which the optical-fiber bare fiber uncovered portion is
inserted, and a second hollow-portion which communicates with this
first hollow portion and has an inner diameter larger than the
outer diameter of the resin-covered portion in the optical fiber
and in which an inserted portion of the resin-covered portion and
an optical-fiber bare fiber uncovered portion standing uncovered
from the resin-covered portion to lead to the first hollow portion
are held; and
[0015] a first conical recessed portion which is provided on the
first hollow portion side of the sleeve main body and to which the
leading end portion of the optical-fiber bare fiber uncovered
portion is uncovered;
[0016] the interior of the first conical recessed portion being
filled with a solder to make the optical-fiber bare fiber uncovered
portion fastened to the metallic sleeve and also make a gap between
the first hollow portion and the optical-fiber bare fiber uncovered
portion being closed with the solder, and a gap between the second
hollow portion and the resin-covered portion being filled with an
adhesive to make the resin-covered portion fastened to the metallic
sleeve.
[0017] According to the optical-fiber feedthrough according to the
present invention, a structure is provided in which the portion
where the optical-fiber bare fiber uncovered portion in the optical
fiber is fastened with a solder to the metallic sleeve and the
portion where the resin-covered portion in the optical fiber is
fastened with an adhesive to the metallic sleeve are separate, and
hence the heat at the time the package is fastened can not easily
be conducted to the resin-covered portion and adhesive in the
optical fiber. Hence, when it is fastened to the package, the
solder can be prevented from re-melt, the adhesive from thermal
deterioration, and the resin-covered portion from thermal
deterioration.
[0018] Thus, sealing treatment making use of a solder having a
higher melting point than any conventional one may be carried out
by a simple method, and the temperature and time in the sealing
treatment may gently be managed. This brings the effect of enabling
the optical communication module to be manufactured stably and to
have highly reliable sealing structure.
[0019] Incidentally, an optical-fiber feedthrough improved in pull
strength required when the optical fiber is pulled may also be made
up by providing a cutout in the second hollow portion of the above
sleeve main body and employing the following structure.
[0020] More specifically, presupposing the above optical-fiber
feedthrough provided with a cutout, a structure may also be made up
in which the leading end portion of the inserted portion of the
optical fiber at its resin-covered portion is disposed at a
position intermediate or substantially intermediate between the
above cutout and the open end portion of the second hollow portion
on its side opposite to the first hollow portion, and the second
hollow portion is filled therein with the adhesive at least up to
an end of the cutout on its first hollow portion side, and also a
hollow is formed between an end of the second hollow portion on its
first hollow portion side and an end of the adhesive on its first
hollow portion side with which adhesive the second hollow portion
is filled.
[0021] According to the optical-fiber feedthrough having such a
structure, the leading end portion of the inserted portion of the
optical fiber at its resin-covered portion is disposed at a
position intermediate or substantially intermediate between the
cutout and the open end portion of the second hollow portion on its
side opposite to the first hollow portion and also the second
hollow portion is filled therein with the adhesive at least up to
an end of the cutout on its first hollow portion side, and hence
the adhesive with which the second hollow portion is filled and the
adhesive which fills out the interior of the cutout are kept in
continuity to produce an anchor effect, and also part of the
optical-fiber bare fiber uncovered portion held in the second
hollow portion is fastened with the adhesive. Hence, the
optical-fiber feedthrough has the effect of being improved in pull
strength required when the optical fiber is pulled. Also, since the
hollow is formed between an end of the second hollow portion on its
first hollow portion side and an end of the adhesive on its first
hollow portion side with which adhesive the second hollow portion
is filled, the optical-fiber feedthrough has the effect of enabling
sealing treatment making use of a solder having a higher melting
point than any conventional one.
[0022] Then, a terminal component part may be set in the metallic
sleeve on its first conical recessed portion side so that an
optical-fiber feedthrough is made up to have a structure in which
this terminal component part is held inside the package.
[0023] More specifically, presupposing the above optical-fiber
feedthrough, an optical-fiber feedthrough may be made up in which a
terminal component part to be held in the package of the optical
communication module is set in the metallic sleeve on its first
conical recessed portion side, where this terminal component part
is constituted of i) a terminal component part main body having a
third hollow portion which has an inner diameter larger than the
outer diameter of the optical-fiber bare fiber uncovered portion
and into which the optical-fiber bare fiber uncovered portion
extending outward from the first conical recessed portion is
inserted and ii) a second conical recessed portion which is
provided in this terminal component part main body on its side
opposite to the metallic sleeve and to which the leading end
portion of the optical-fiber bare fiber uncovered portion is
uncovered, and also the interior of this second conical recessed
portion is filled with a solder to make the optical-fiber bare
fiber uncovered portion fastened to the terminal component part and
a gap between the third hollow portion and the optical-fiber bare
fiber uncovered portion is closed with the solder.
[0024] In this case, a structure may be employed in which an
auxiliary cylindrical portion is provided which extends outward
from the peripheral edge portion of the second conical recessed
portion in the above terminal component part main body, and also
has a sixth hollow portion which communicates with the third hollow
portion and has an inner diameter larger than this third hollow
portion, to protect the leading end of the optical-fiber bare fiber
uncovered portion standing uncovered from the second conical
recessed portion.
[0025] As a modification, an optical-fiber feedthrough may also be
made up in which the terminal component part to be held inside the
package of the optical communication module is set in the metallic
sleeve on its first conical recessed portion side, where this
terminal component part is constituted of i) a terminal component
part main body having a fourth hollow portion which has an inner
diameter larger than the outer diameter of the optical-fiber bare
fiber uncovered portion and into which the optical-fiber bare fiber
uncovered portion is inserted and a fifth hollow portion which
communicates with this fourth hollow portion and has an inner
diameter larger than the fourth hollow portion and in which the
optical-fiber bare fiber uncovered portion extending outward from
the first conical recessed portion of the metallic sleeve is held
and ii) a second conical recessed portion which is provided in this
terminal component part main body on its side opposite to the
metallic sleeve and to which the leading end portion of the
optical-fiber bare fiber uncovered portion is uncovered, and also
the interior of this second conical recessed portion is filled with
a solder to make the optical-fiber bare fiber uncovered portion
fastened to the terminal component part and a gap between the
fourth hollow portion and the optical-fiber bare fiber uncovered
portion is closed with the solder.
[0026] In this case, a structure may be employed in which an
auxiliary cylindrical portion is provided which extends outward
from the peripheral edge portion of the second conical recessed
portion in the above terminal component part main body, and also
has a sixth hollow portion which communicates with the fourth
hollow portion and has an inner diameter larger than this fourth
hollow portion, to protect the leading end of the optical-fiber
bare fiber uncovered portion standing uncovered from the second
conical recessed portion.
BRIEF DESCRIPTION OF THE DRAWINGS
[0027] FIG. 1 is a schematic front elevation of an optical-fiber
feedthrough according to a first embodiment of the present
invention.
[0028] FIG. 2 is a vertical section of the one shown in FIG. 1.
[0029] FIG. 3 is a sectional view of the construction of a
modification of the optical-fiber feedthrough according to the
first embodiment.
[0030] FIG. 4 is a sectional view of the construction of a
modification of the optical-fiber feedthrough according to the
first embodiment.
[0031] FIG. 5 is a sectional view of the construction of a
modification of the optical-fiber feedthrough according to the
first embodiment.
[0032] FIG. 6 is a sectional view of the construction of a metallic
sleeve which constitutes part of an optical-fiber feedthrough
according to a second embodiment of the present invention.
[0033] FIG. 7 is a sectional view of the construction of a terminal
component part which constitutes part of the optical-fiber
feedthrough according to the second embodiment of the present
invention.
[0034] FIG. 8 is a sectional view of the construction of the
optical-fiber feedthrough according to the second embodiment of the
present invention.
[0035] FIG. 9 is a sectional view of the construction of the
terminal component part according to its modification.
[0036] FIG. 10 is a sectional view of the construction of a
modification of the optical-fiber feedthrough according to the
second embodiment of the present invention.
[0037] FIG. 11 is a sectional view of the construction of a
modification of the optical-fiber feedthrough according to the
second embodiment of the present invention.
[0038] FIG. 12(A) is a schematic front elevation of a metallic
sleeve which constitutes part of an optical-fiber feedthrough
according to a third embodiment of the present invention, and FIG.
12(B) is a vertical section of the one shown in FIG. 12(A).
[0039] FIG. 13 is a sectional view of the construction of a
terminal component part which constitutes part of an optical-fiber
feedthrough according to a fourth embodiment of the present
invention.
[0040] FIG. 14 is a sectional view of the construction of a
terminal component part according to a modification of the second
embodiment.
[0041] FIGS. 15(A) and 15(B) are illustrations showing the step of
attachment to fasten the leading end of an optical-fiber bare fiber
to the terminal component part by feeding solder balls to a second
conical recessed portion in the terminal component part (a
modification) according to the second embodiment.
[0042] FIG. 16(A) is a schematic front elevation showing how solder
balls are fed into an auxiliary cylindrical portion of a terminal
component part according to a fourth embodiment, and FIG. 16(B) is
its vertical section.
BEST MODES FOR PRACTICING THE INVENTION
[0043] To describe the present invention in greater detail, the
present invention is described with reference to the accompanying
drawings.
[0044] Incidentally, FIG. 1 presents a schematic front elevation of
an optical-fiber feedthrough according to a first embodiment of the
present invention. FIG. 2 presents a vertical section of the one
shown in FIG. 1.
[0045] (First Embodiment)
[0046] First, as shown in FIGS. 1 and 2, the optical-fiber
feedthrough according to this embodiment is constituted of a
metallic sleeve 1 and an optical fiber 2 fastened to this metallic
sleeve 1, and the optical fiber 2 is constituted of an
optical-fiber bare fiber uncovered portion 3 and a resin-covered
portion 5 with which the outer surface of the former is covered. On
the outer surface of the optical-fiber bare fiber, a metallic film
is provided which is constituted of a subbing layer formed of an Ni
plating layer and a surface layer formed of an Au plating
layer.
[0047] The metallic sleeve 1 is constituted of i) a sleeve main
body having a first hollow portion 9 which has an inner diameter
larger than the outer diameter of the optical-fiber bare fiber
uncovered portion 3 in the optical fiber 2 and into which the
optical-fiber bare fiber uncovered portion 3 is inserted, and a
second hollow portion 8 which communicates with the first hollow
portion 9 and has an inner diameter larger than the outer diameter
of the resin-covered portion 5 in the optical fiber 2 and in which
an inserted portion of the resin-covered portion 5 and an
optical-fiber bare fiber uncovered portion 3 standing uncovered
from the resin-covered portion 5 to lead to the first hollow
portion 9 are held, and ii) a first conical recessed portion 10
which is provided on the first hollow portion side of the sleeve
main body and to which the leading end portion of the optical-fiber
bare fiber uncovered portion 3 is uncovered. Also, a cutout 7
having substantially the same radius as the second hollow portion 8
is holed at substantially the middle portion of the second hollow
portion 8. Incidentally, in this embodiment, SUS304 is used in the
metallic sleeve 1, and a subbing layer formed of an Ni and/or Cr
plating layer and a surface layer formed of an Au plating layer are
formed on the surface of the metallic sleeve.
[0048] Between the metallic sleeve 1 and the optical fiber 2, the
both are fastened in the following way. That is, the interior of
the first conical recessed portion 10 in the metallic sleeve 1 is
filled with solder (Au/20Sn eutectic solder) 4 to make the
optical-fiber bare fiber uncovered portion 3 fastened to the
metallic sleeve 1, and also a gap between the second hollow portion
8 and the resin-covered portion 5 is filled with an adhesive 6 to
make the resin-covered portion 5 fastened to the metallic sleeve
1.
[0049] Incidentally, since the interior of the first conical
recessed portion 10 is filled with the solder 4, the interior of
the first conical recessed portion 10 is made full with the solder
4, and a gap between the first hollow portion 9 and the
optical-fiber bare fiber uncovered portion 3 is also filled with
part of the solder 4, so that the gap between these is closed with
the solder 4.
[0050] To describe the above in greater detail, in the first
conical recessed portion 10 the optical-fiber bare fiber uncovered
portion 3 and the metallic sleeve 1 are fastened to each other by
feeding the solder (Au/20Sn eutectic solder) into the first conical
recessed portion 10, and thereafter heating the first conical
recessed portion 10 from the outside of the metallic sleeve 1 to
make the solder melt and also make it solidify. In this case,
heating temperature is so controlled that the temperature at the
head of the heater comes to be 420.degree. C. Also, the time of the
heating effected in contact with the heater has been found
favorable to be from 10 seconds to 15 seconds taking account of the
melt time and flow time of the solder.
[0051] An He leak test was conducted on the part soldered in this
way (i.e., the gap between the first hollow portion 9 and the
optical-fiber bare fiber uncovered portion 3 in the metallic sleeve
1) to find that a leak was at a rate of 1.times.10.sup.-9
Pa.multidot.m.sup.3/s or less, where a high airtightness was
maintained. Effects of heat on the resin-covered portion 5 of the
optical fiber were also examined to find that any effects such as
thermal deterioration and melting were not seen.
[0052] The leading end portion (package attachment part 11 which is
a portion vicinal to the first conical recessed portion 10) of the
optical-fiber feedthrough according to First Embodiment, having
such structure, was fastened with solder (Sn/38Pb eutectic solder)
to the package sidewall of the optical communication module. As a
result, different from any conventional optical-fiber feedthrough,
none of re-melt of the solder 4 at the first conical recessed
portion 10, thermal deterioration of the adhesive 6 and thermal
deterioration of the resin-covered portion 5 were seen, and also
any break of the optical-fiber bare fiber did not occur.
[0053] That is, in the optical-fiber feedthrough according to this
embodiment, the portion where the optical-fiber bare fiber
uncovered portion 3 in the optical fiber 2 is fastened with the
solder 4 to the metallic sleeve 1 and the portion where the
resin-covered portion 5 in the optical fiber is fastened with an
adhesive to the metallic sleeve 1 are separate, and hence the heat
at the time the package is fastened can not easily be conducted to
the resin-covered portion 5 and adhesive 6 in the optical fiber.
Also, a space is present inside the second hollow portion 8 of the
metallic sleeve 1 at its portion extending from an end of the
resin-covered portion 5 to the first hollow portion. 9 and besides
the cutout 7 communicating with the outside is provided at the
second hollow portion 8, and hence a structure is provided that
enables the heat inside the metallic sleeve 1 to be radiated
outside with ease. Hence, when it is fastened to the package, the
solder 4 can be prevented from re-melt, the adhesive 6 from thermal
deterioration, and the resin-covered portion 5 from thermal
deterioration.
[0054] Thus, this makes it possible to provide an optical-fiber
feedthrough whose optical-fiber bare fiber can not easily be broken
when it is attached to the package sidewall of the optical
communication module.
[0055] Incidentally, as to the cutout 7 provided at the second
hollow portion 8, it may be omitted as shown in FIG. 3. Even if it
is, it is possible to obtain the same effect as that the
optical-fiber feedthrough shown in FIGS. 1 and 2 has.
[0056] In the optical-fiber feedthrough shown in FIGS. 1 and 2, the
metallic sleeve 1 is made up of a single constituent member. It,
however, may have a structure in which, as shown in FIG. 4, it is
constituted of a cylindrical main body 100 provided with the cutout
7, and a fitting member 101 which is fitted in this cylindrical
main body 100 on its one open-end side and at the center of which
the first hollow portion 9 is bored, and also which forms the first
conical recessed portion 10 together with the open end portion of
the cylindrical main body 100. Similarly, as to the optical-fiber
feedthrough shown in FIG. 3, too, having no cutout 7, a method may
be employed in which, as shown in FIG. 5, it is constituted of a
cylindrical main body 100, and a fitting member 101 which is fitted
in this cylindrical main body 100 on its one open-end side and at
the center of which the first hollow portion 9 is bored, and also
which forms the first conical recessed portion 10 together with the
open end portion of the cylindrical main body 100.
[0057] (Second Embodiment)
[0058] First, the optical-fiber feedthrough according to this
embodiment has substantially the same structure as the
optical-fiber feedthrough according to First Embodiment shown in
FIGS. 1 and 2, except that as shown in FIG. 6 the outer diameter of
the metallic sleeve 1 at a portion around the first hollow portion
9 is set larger than the outer diameter of the metallic sleeve 1 at
its second hollow portion 8 and that a terminal component part is
set in the metallic sleeve 1 on its first conical recessed portion
10 side, in order that a terminal component part to be held inside
the package of the optical communication module is set in the
metallic sleeve 1 on its first conical recessed portion 10
side.
[0059] The terminal component part 20 to be set in on the first
conical recessed portion 10 side is, as shown in FIG. 7,
constituted of i) a terminal component part main body having a
third hollow portion 22 which has an inner diameter larger than the
outer diameter of the optical-fiber bare fiber uncovered portion 3
and into which the optical-fiber bare fiber uncovered portion 3
extending outward from the first conical recessed portion 10 is
inserted and ii) a second conical recessed portion 21 which is
provided in this terminal component part main body on its side
opposite to the metallic sleeve 1 and to which the leading end
portion of the optical-fiber bare fiber uncovered portion 3 is
uncovered.
[0060] The interior of the second conical recessed portion 21 is
also filled with solder (Au/20Sn eutectic solder) 24 to make the
optical-fiber bare fiber uncovered portion 3 fastened to the
terminal component part 20 and a gap between the third hollow
portion 22 and the optical-fiber bare fiber uncovered portion 3 is
closed with the solder 24. As shown in FIG. 8, the terminal
component part 20 is set in the metallic sleeve 1 on its first
conical recessed portion 10 side. Incidentally, in soldering the
terminal component part 20, it has been ascertained that good
joining can be made, as a result of observation of the state of
joining where the temperature of a heater section is changed to
range from 380.degree. C. to 470.degree. C. and the heating time is
changed to range from 10 seconds to 20 seconds.
[0061] Here, as the material of the terminal component part 20,
SUS304 is used like the metallic sleeve 1, and a subbing layer
formed of an Ni and/or Cr plating layer and a surface layer formed
of an Au plating layer are formed on its surface. Incidentally, in
this embodiment, whole-area Au plating is applied as the surface
layer taking account of the fact that the optical-fiber feedthrough
is fastened to the optical communication module by soldering.
However, where a welder such as a YAG laser is used when fastened
to the optical communication module, it is desirable to apply the
Au plating only to the soldering part.
[0062] In the optical-fiber feedthrough according to this
embodiment, when used, the leading end portion (package attachment
part 11, the portion where the metallic sleeve 1 has a large
diameter) of the metallic sleeve 1 is fastened with, e.g., solder
(Sn/38Pb eutectic solder) to the package sidewall of the optical
communication module, and the terminal component part 20 set in on
the leading end side farther than the first conical recessed
portion 10 is held in the package of the optical communication
module.
[0063] In the optical-fiber feedthrough according to this
embodiment, too, its leading end portion was fastened with solder
(Sn/38Pb eutectic solder) to the package sidewall of the optical
communication module, where, different from any conventional
optical-fiber feedthrough, none of re-melt of the solder 4 at the
first conical recessed portion 10, thermal deterioration of the
adhesive 6 and thermal deterioration of the resin-covered portion 5
were seen, and also any break of the optical-fiber bare fiber did
not occur.
[0064] Next, FIG. 9 is a sectional view of the construction of the
terminal component part 20 according to its modification. More
specifically, as shown in FIG. 9 the terminal component part 20
according to its modification is constituted of i) a terminal
component part main body having a fourth hollow portion 23 which
has an inner diameter larger than the outer diameter of the
optical-fiber bare fiber uncovered portion 3 and into which the
optical-fiber bare fiber uncovered portion 3 is inserted and a
fifth hollow portion 25 which communicates with the fourth hollow
portion 23 and has an inner diameter larger than the fourth hollow
portion 23 and in which the optical-fiber bare fiber uncovered
portion 3 extending outward from the first conical recessed portion
10 of the metallic sleeve 1 is held and ii) a second conical
recessed portion 21 which is provided in this terminal component
part main body on its side opposite to the metallic sleeve 1 and to
which the leading end portion of the optical-fiber bare fiber
uncovered portion 3 is uncovered.
[0065] The interior of the second conical recessed portion 21 is
also filled with solder (Au/20Sn eutectic solder) 24 to make the
optical-fiber bare fiber uncovered portion 3 fastened to the
terminal component part 20 and a gap between the fourth hollow
portion 23 and the optical-fiber bare fiber uncovered portion 3 is
closed with the solder 24. As shown in FIG. 10, the terminal
component part 20 is set in the metallic sleeve 1 on its first
conical recessed portion 10 side.
[0066] Incidentally, in the optical-fiber feedthrough according to
this embodiment, too, when used, the leading end portion (the
portion where the metallic sleeve 1 has a large diameter) of the
metallic sleeve 1 is fastened with, e.g., solder (Sn/38Pb eutectic
solder) to the package sidewall of the optical communication
module, and the terminal component part 20 set in on the leading
end side farther than the first conical recessed portion 10 is held
in the package of the optical communication module.
[0067] In the optical-fiber feedthrough according to this
embodiment, too, its leading end portion was fastened with solder
(Sn/38Pb eutectic solder) to the package sidewall of the optical
communication module, where, different from any conventional
optical-fiber feedthrough, none of re-melt of the solder 4 at the
first conical recessed portion 10, thermal deterioration of the
adhesive 6 and thermal deterioration of the resin-covered portion 5
were seen, and also any break of the optical-fiber bare fiber did
not occur.
[0068] In addition, in the optical-fiber feedthrough according to
this embodiment, the fifth hollow portion 25 of the terminal
component part 20 has a large inner diameter. Hence, even when as
shown in FIG. 11 the terminal component part 20 was moved by 0.3 mm
in parallel to its axis, a load was not easily applied to the
optical-fiber bare fiber uncovered portion 3, and any troubles such
as deformation, peel and break were not seen at every part.
[0069] (Third Embodiment)
[0070] The optical-fiber feedthrough according to this embodiment
is, as shown in FIGS. 12(A) and 12(B), substantially the same as
the optical-fiber feedthrough according to Second Embodiment except
that the position of the cutout 7 formed at the second hollow
portion 8 is set somewhat near to the first hollow portion 9 side
compared with the FIG. 6 metallic sleeve 1 according to Second
Embodiment, that the position of the leading end of the
resin-covered portion 5 inserted into the second hollow portion 8
is set at a position substantially intermediate between the above
cutout 7 and the open end portion of the second hollow portion 8 on
its side opposite to the first hollow portion 9 and that the second
hollow portion 8 is filled with the adhesive 6 up to an end of the
cutout 7 on its first hollow portion 9 side. Incidentally, as shown
in FIG. 12(B), a hollow 200 is formed between an end of the second
hollow portion 8 on its first hollow portion 9 side and an end of
the adhesive 6 on its first hollow portion 9 side with which
adhesive the second hollow portion 8 is filled. Also, the cutout 7
has a circular shape of 0.5 mm in inner diameter.
[0071] In the optical-fiber feedthrough according to this
embodiment, as shown in FIG. 12(B) the adhesive 6 with which the
second hollow portion 8 is filled and the adhesive which fills out
the interior of the cutout 7 are kept in continuity to produce an
anchor effect, and also part of the optical-fiber bare fiber
uncovered portion 3 held in the second hollow portion 8 is fastened
with the adhesive 6. Hence, compared with the optical-fiber
feedthrough according to Second Embodiment, the optical-fiber
feedthrough has an advantage that its pull strength required when
the optical fiber is pulled is greatly improved (i.e., the optical
fiber can not easily be pulled out compared with the optical-fiber
feedthrough according to Second Embodiment).
[0072] In addition, the hollow 200 is formed between an end of the
second hollow portion 8 on its first hollow portion 9 side and an
end of the adhesive 6 on its first hollow portion 9 side with which
adhesive the second hollow portion 8 is filled. Hence, where the
leading end portion (package attachment part 11 which is a portion
vicinal to the first conical recessed portion 10) of this
optical-fiber feedthrough according to Third Embodiment was
fastened with solder (Sn/38Pb eutectic solder) to the package
sidewall of the optical communication module, different from any
conventional optical-fiber feedthrough, none of re-melt of the
solder 4 at the first conical recessed portion 10, thermal
deterioration of the adhesive 6 and thermal deterioration of the
resin-covered portion 5 were seen, and also any break of the
optical-fiber bare fiber did not occur.
[0073] Incidentally, as to the cutout 7 formed at the second hollow
portion 8, those in which its inner diameter was set to less than
0.2 mm and those in which its inner diameter was set to more than
0.9 mm were taken to make up similar optical-fiber feedthroughs
experimentally, and their effect was confirmed. As a result, it has
proved that, as to the former those of less than 0.2 mm in inner
diameter, it is somewhat difficult in some cases to fill the
interior with the adhesive 6 when it is attempted to do so up to
the portion of the optical-fiber bare fiber uncovered portion 3
held in the second hollow portion 8, and that the above anchor
effect also comes weak. On the other hand, as to those of more than
0.9 mm in inner diameter, it has proved that difficulties may arise
such that the interior of the second hollow portion 8 is filled
with the adhesive 6 in excess to make it difficult to form the
hollow 200 and that the adhesive 6 having overflowed from the
cutout 7 covers the outer surface of the metallic sleeve 1.
Accordingly, in order to prevent such difficulties surely, the
inner diameter of the cutout 7 formed at the second hollow portion
8 may preferably be set to from 0.2 mm or more to 0.9 mm or
less.
[0074] (Fourth Embodiment)
[0075] The optical-fiber feedthrough according to this embodiment
is, as shown in FIG. 13, substantially the same as the
optical-fiber feedthrough according to Second Embodiment except
that, compared with the terminal component part 20 according to the
modification of Second Embodiment as shown in FIG. 9, an auxiliary
cylindrical portion 300 which extends outward from the peripheral
edge portion of the second conical recessed portion 21 is provided
at this portion in the terminal component part main body and that
the leading end portion of the optical-fiber bare fiber uncovered
portion 3 standing uncovered from the second conical recessed
portion 21 has been subjected to end face treatment for optical
coupling.
[0076] More specifically, as shown in FIG. 13, the auxiliary
cylindrical portion 300 has a sixth hollow portion 301 which
communicates with the fourth hollow portion 23 and has an inner
diameter larger than this fourth hollow portion 23. Also, at this
sixth hollow portion 301, a cutout 302 is holed which is to confirm
therethrough the leading end portion of the optical-fiber bare
fiber uncovered portion 3 held in the auxiliary cylindrical portion
300. The leading end portion of the optical-fiber bare fiber
uncovered portion 3 standing uncovered from the second conical
recessed portion 21 has also been subjected to end face treatment
for optical coupling by which its end face is polished, or cut by
cleaving, so as to be finished to have an optically favorable
state.
[0077] In the optical-fiber feedthrough according to this
embodiment, as shown in FIG. 13, the auxiliary cylindrical portion
300 is provided at the second conical recessed portion 21 of the
terminal component part main body in the terminal component part
20. Hence, compared with the terminal component part 20 according
to the modification of Second Embodiment as shown in FIG. 9, not
having this auxiliary cylindrical portion, the present
optical-fiber feedthrough has an advantage that the leading end
portion of the optical-fiber bare fiber uncovered portion 3
standing uncovered from the second conical recessed portion 21 can
not easily be broken (see the terminal component part 20 according
to a modification of Second Embodiment as shown in FIG. 14) when,
e.g., the optical-fiber feedthrough is assembled.
[0078] In the terminal component part 20 according to the
modification of Second Embodiment as shown in FIG. 14, a method is
also employed in which a gap between the fourth hollow portion 23
and the optical-fiber bare fiber uncovered portion 3 inserted to
the former is closed to fasten them, using Au/20Sn solder eutectic
balls of about 0.3 mm in outer diameter. However, as shown in FIGS.
15(A) and 15(B), as to the solder eutectic balls to be held in the
second conical recessed portion 21, the space for their holding is
limited, and hence it is difficult to set their quantity large. If
their quantity is set large, the molten solder may cover the
leading end of the optical-fiber bare fiber uncovered portion
3.
[0079] To cope with such a problem, in the optical-fiber
feedthrough according to this embodiment, the auxiliary cylindrical
portion 300 is provided at the second conical recessed portion 21
of the terminal component part 20. Hence, as to the solder eutectic
balls to be held in the second conical recessed portion 21, their
quantity can be set larger insofar as the space for their holding
can be wider as shown in FIGS. 16(A) and 16(B).
[0080] Thus, the present optical-fiber feedthrough has an advantage
that, insofar as the solder eutectic balls to be fed can be in a
larger quantity, the strength can also be higher at which the
optical-fiber bare fiber uncovered portion 3 inserted into the
fourth hollow portion 23 is fastened at the gap between them. Also,
at this sixth hollow portion 301, the cutout 302 is holed which is
to confirm therethrough the leading end portion of the
optical-fiber bare fiber uncovered portion 3 held in the auxiliary
cylindrical portion 300. Hence, although the auxiliary cylindrical
portion 300 is additionally provided, there can be no obstacle to
the operation for making the solder eutectic balls held in the
second conical recessed portion 21.
POSSIBILITY OF INDUSTRIAL APPLICATION
[0081] As described above, in the optical-fiber feedthrough
according to the present invention, the structure is provided in
which the portion where the optical-fiber bare fiber uncovered
portion in the optical fiber is fastened with a solder to the
metallic sleeve and the portion where the resin-covered portion in
the optical fiber is fastened with an adhesive to the metallic
sleeve are separate, and hence the heat at the time the package is
fastened can not easily be conducted to the resin-covered portion
and adhesive in the optical fiber. Hence, when it is fastened to
the package, the solder can be prevented from re-melt, the adhesive
from thermal deterioration, and the resin-covered portion from
thermal deterioration.
[0082] Accordingly, sealing treatment making use of a solder having
a higher melting point than any conventional one may be carried out
by a simple method, and the temperature and time in the sealing
treatment may gently be managed, and hence the present invention is
suited for use as an optical-fiber feedthrough which provides
stable manufacture and highly reliable optical communication module
sealing structure.
* * * * *